Abstract
Effects of the quantum interference in collisions of particles have a twofold nature: they arise because of the auto-correlation of a complex scattering amplitude and due to spatial coherence of the incoming wave packets. Both these effects are neglected in a conventional scattering theory dealing with the delocalized plane waves, although they sometimes must be taken into account in particle and atomic physics. Here, we study the role of a transverse coherence length of the packets, putting special emphasis on the case in which one of the particles is twisted, that is, it carries an orbital angular momentum $\ell\hbar$. In $ee, ep$, and $pp$ collisions the interference results in corrections to the plane-wave cross sections, usually negligible at the energies $\sqrt{s} \gg 1$ GeV but noticeable for smaller ones, especially if there is a twisted hadron with $|\ell| > 10^3$ in initial state. Beyond the perturbative QCD, these corrections become only moderately attenuated allowing one to probe a phase of the hadronic amplitude as a function of $s$ and $t$. In this regime, the coherence effects can compete with the loop corrections in QED and facilitate testing the phenomenological models of the strong interaction at intermediate and low energies.
Highlights
Scattering outcomes generally depend on the quantum states of particles brought into collisions
While a conventional scattering theory deals with the delocalized planewaves having definite momenta, it is not applicable to a number of realistic scenarios—for instance, when the particles collide at large impact parameters [1], if they are unstable [2,3], or if their quantum states are different from the simplified plane-waves [4,5,6,7,8,9,10,11,12,13,14,15,16,17]
We study the role of the transverse coherence length of packets in relativistic collisions, putting special emphasis on the case in which one of the incoming particles is twisted
Summary
Scattering outcomes generally depend on the quantum states of particles brought into collisions. While a conventional scattering theory deals with the delocalized planewaves having definite momenta, it is not applicable to a number of realistic scenarios—for instance, when the particles collide at large impact parameters [1], if they are unstable [2,3], or if their quantum states are different from the simplified plane-waves [4,5,6,7,8,9,10,11,12,13,14,15,16,17] Such states as the so-called twisted photons, the Airy beams, the squeezed states, the Schrödinger’s cat states, and so on have been studied for years, both theoretically and experimentally (see, e.g., [18,19,20,21,22,23]). The system of units ħ 1⁄4 c 1⁄4 1 is used
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